Amplifier for high frequency signal

ABSTRACT

In an amplifier for a high frequency signal used to amplify a signal having a high frequency in a television tuner, a receiver for satellite broadcasting, and the like, at least two stages of dc-coupled grounded-emitter type amplifiers (Q 1 , Q 2 ) are configured in an integrated circuit, a resistor (R 13 ) is connected between an emitter of the grounded-emitter amplifier (Q 2 ) in the second stage and the grounding, a terminal for connecting an external device is disposed to be connected via a bonding wire to the emitter of the grounded-emitter amplifier (Q 2 ) in the second stage, and a filter circuit (11) including an inductance of the bonding wire and developing a low impedance for a particular frequency is disposed between the terminal and the external grounding.

TECHNICAL FIELD

The present invention relates to an amplifier for a high frequency signal used to amplify a high frequency signal in a television tuner, a receiver for satellite broadcasing, or the like.

BACKGROUND ART

In the prior art, in order to obtain a high gain in an amplifier circuit for a high frequency signal for processing a high frequency signal of which the frequency is at least in the 100 MHz band, a multistage cascade circuit of the grounded-emitter type amplifier as shown in FIG. 1A has been commonly used. In FIG. 1A, a high frequency signal is supplied from an input terminal IN and is amplified by two stages of transistors Q₁ and Q₂, and then is delivered from an output terminal OUT. To integrate the circuit of FIG. 1A, the configuration must be sealed in an IC package 1 as shown in FIG. 1B. Since the pins 1a, 1b, 1c, and 1d of the IC package 1 are connected to the IC chip by use of bonding wires, the circuit include wire inductances such as L_(in), L_(G), L_(out), and L_(B) shown in FIG. 1B. These wire inductances are ordinarily of a value from 2.5 nH to 5 nH, which is ignorable for a lower frequency. For a high frequency signal of which the frequency is at least 800 MHz, the wire inductance cannot be ignored. In the circuit of FIG. 1, the influence of the wire inductances L_(IN), L_(B), and L_(out) can be removed by use of an external circuit or resistors R₁, R₃, and R₄ in the IC; however, the influence of the inductance L_(G) inserted between the circuit and a grounding (GND) cannot be eliminated. In the example of this figure, it particularly causes a problem that the common inductance component is inserted for the emitters of the transistors Q₁ and Q₂, which configures a feedback loop and therefore leads to a serious drawback that the circuit starts oscillation. In FIG. 1C, a resistor R₅ is inserted into the emitter of the transistor Q₂ of FIG. 1B and the bonding wire inductance L_(G2) is grounded through a bypass capacitor C connected externally with respect to the IC, thereby attempting to improve the oscillation described above. Although any problem may not arise in the case with only the transistor Q₁, if the transistors Q₁ and Q₂ are connected, the emitter of the transistor Q₁ is connected to the grounding in the IC, that is, there exists the wire inductance L_(G1) in addition to the wire inductance L_(G2), which makes the grounding potential of the circuit unstable; consequently, even if no problem is caused in the case including only the wire inductance L_(G1), the circuit has a drawback that the oscillation state cannot be prevented in the multistage casecade connection.

DISCLOSURE OF INVENTION

An object of the present invention is to provide in such a multistage cascade integrated circuit system for a high frequency signal an amplifier for a high frequency which is capable of obtaining a stable operation without causing the oscillation phenomenon.

Another object of the present invention is to provide an amplifier for a high frequency signal which can easily achieve an operation to attain a sharp frequency characteristic and a phase shift operation.

Still another object of the present invention is to provide an amplifier for a high frequency signal which is capable of improving the gain without increasing the number of elements and the current consumption.

Another object of the present invention is to provide an amplifier for a high frequency signal which can remove the image disturbance by use of a simple configuration.

The amplifier for a high frequency signal according to the present invention includes an integrated circuit configured by a circuit in which at least two stages of grounded-emitter type amplifiers are connected by use of a direct current coupling, furthermore an emitter resistor is connected between an emitter of the second-stage amplifier and the grounding, at least a terminal of said second-stage amplifier is connected via a bonding wire of the integrated circuit to a terminal disposed externally with respect to the integrated circuit, a filter circuit including the inductance associated with the terminal is configured with respect to the grounding, and a signal having a particular frequency is connected by the filter circuit to a grounding outside the integrated circuit, thereby preventing the feedback due to the emitter resistor so as to increase the gain.

BRIEF DESCRIPTION OF DRAWINGS

FIGS. 1A, 1B and 1C are circuit diagrams of the conventional amplifier for a high frequency signal, FIG. 2 is a circuit diagram of an amplifier for a high frequency signal according to an embodiment of the present invention, FIG. 3 and FIG. 5 are frequency-amplitude characteristic diagrams of the system of FIG. 2, FIG. 4 is a concrete circuit diagram of a filter circuit 12 of FIG. 2, FIG. 6 is a block diagram of an amplifier for a high frequency signal according to another embodiment of the present invention, FIG. 7 is a concrete circuit diagram of FIG. 6, FIGS. 8A, 8B are concrete circuit diagrams of a filter circuit 25 of FIG. 7, FIG. 9 is a block diagram of a converter using an amplifier for a high frequency signal as a first intermediate amplifier, FIG. 10 is a block diagram of a converter solving the drawback of the configuration of FIG. 9, FIG. 11 is a concrete circuit diagram of the primary section of FIG. 10, FIG. 12 is a characteristic diagram of a trap circuit of FIG. 11, FIG. 13 is a characteristic diagram of a band-pass filter using a surface wave filter, and FIGS. 14A, 14B are a circuit diagram and a characteristic diagram showing another example of the trap circuit.

BEST MODE FOR CARRYING OUT THE INVENTION

A description will be given herebelow of an embodiment of the amplifier for a high frequency signal according to the present invention with reference to the accompanying drawings. FIG. 2 shows an embodiment of the present invention. The amplifier for a high frequency signal of this diagram comprises an integrated circuit chip, a package, and bonding wires linking the chip to the package. The IC of this figure is of a 7-pin configuration in which a wire inductance configured by a bonding wire is formed between each pin and a terminal of the package. In this diagram, these inductances are represented as L₁ -L₇ in an equivalent circuit. The wire inductance varies depending on the thickness and length of the wire and is ordinarily of a value from about 2.5 nH to 5 nH. An input signal is supplied from an input terminal IN and is fed via a coupling capacitor C₁ to pin ○1 , and is further delivered via the wire inductance L₁ to a base of an amplifying transistor Q₁ constituting a grounding-emitter type amplifier in the integrated circuit. The transistor Q₁ has an emitter connected to a grounding in the chip, which in turn is connected via the wire inductance L₂ to pin ○2 , which is further connected to an external grounding. The transistor Q₁ has a collector connected via a load resistor R₁₁ to a regulated voltage V_(const) line in the chip.

A signal amplified by the transistor Q₁ is delivered from the collector thereof to pin ○3 via the wire inductance L₃, and is further supplied via an external filter circuit 12 to pin ○4 , and is then fed via the wire inductance L₄ to a base of an amplifying transistor Q₂ constituting a grounded-emitter type amplifier. The collector of the transistor Q₁ and the base of the transistor Q₂ are connected by a resistor R₁₂ having a high resistance (ordinarily 1KΩ or more) with respect to a direct current (dc). The collector of the transistor Q₂ is connected via a load resistor R₁₆ to the regulated voltage V_(const) line. The collector of the transistor Q₂ is connected via the wire inductance L₆ to pin ○6 , and is further led via a coupling capacitor C₃ to an external device. The emitter of the transistor Q₂ supplies signals to three directions. The first signal path is fed via the wire inductance L₅ to pin ○5 , and is then connected via a resonance capacitor C₂ and a dumping resistor R₂₀ to the external grounding. The second signal path is connected via a resistor R₁₃ to the grounding in the chip; moreover, the third signal path is connected so that a divided potential divided by resistors R₁₄ and R₁₅ is supplied to the base of the transistor Q₁, thereby establishing a negative feedback for the transistors Q₁ and Q₂. The regulated voltage V_(const) in the chip is supplied after being subjected to a current amplification through an emitter follower comprising a transistor Q₃ and resistors R₁₉ and R₁₈. The regulated voltage V_(const) is attained by use of the zener characteristic between the emitter and the base of a transistor Q₄. Transistors Q₅ to Q₇ are used as diodes; consequently, the base of the transistor Q₃ is supplied via the resistor R₁₈ (about 200 Ω) a potential which is higher than the zener potential of the transistor Q₄ by a potential equivalent to three diodes. The power supply voltage V_(cc) (about 12 V) is supplied from pin ○7 to the resistors R₁₈ and R₁₇ via the wire inductance L₇.

A current flows into the collector of the transistor Q₁ through the regulated voltage V_(const) line via the resistor R₁₁, and the current branches into the base of the transistor Q₂. A current flows into the collector of the transistor Q₂ through the regulated voltage V_(const) line via the resistor R₁₂. The sum of the base current of the transistor Q₂ and the current passing through the resistor R₁₆ flows into the emitter of the transistor Q₂, and is further fed via the resistor R₁₃ to the grounding (GND); consequently, a potential determined by a product of the value of the resistor R₁₃ and the emitter current of the transistor Q₂ appears accross the resistor R₁₃. If this potential is fed back to the base of the transistor Q₁ via the resistor R₁₄, the base potential of the transistor Q₁ increases, the collector potential of the transistor Q₁ decreases, and the emitter potential of the transistor Q₂ decreases; as a result, the base potential of the transistor Q₁ is stabilized at a fixed point, and hence a desired current can be passed through the transistors Q₁ and Q₂, respectively by appropriately selecting the values of the resistors R₁₁, R₁₃, R₁₄, and R₁₅. In such a state, although the input signal is amplified by the transistors Q₁ and Q₂, the gain cannot be obtained with respect to a high frequency signal because of the emitter resistor R₁₃ of the transistor Q₂. To overcome this difficulty, a filter circuit 11 is here inserted between the emitter of the transistor Q₂ and the grounding so as to decrease the feedback amount of a signal having a specific frequency, thereby stabilizing the circuit operation. The resistor R₁₅ in this diagram is inserted to adjust the amount of the direct current to be fed back by use of the resistor R₁₄.

As shown in the diagram, when the circuit is integrated and is housed in an IC package, the IC chip and the package are connected by use of bonding wires, which results in the wire inductances L₁ -L₇ as depicted in the figure. These values range from 2.5 nH to 5 nH as described before, and the influence of the wire inductances L₁ and L₆ can be removed as already noted before; however, the two inductances L₂ and L₅ each have a strong influence with respect to an alternating current (ac), and each influence respectively causes the circuit to become unstable in its operation, thereby leading to the oscillation state. Consequently, at most only one of the bonding wire inductances L₂ and L₅ is allowed.

In this example, therefore, the wire bonding inductance L₅ is removed so as to ensure the stability of the circuit. As shown in the diagram, the filter circuit is disposed outside the IC package so that a resonance occurs due to the filter circuit 11 and the wire inductance L₅, thereby establishing a function to absorb the wire inductance component. As the filter circuit 11, a series resonance circuit is constituted with the bonding wire inductance L₅ and the capacitor C₂ as shown in the figure so as to remove the influence of the wire inductance L₅ and further to eliminate the effect of the emitter resistor R₁₃ of the transistor Q₂ in the neighborhood of the desired frequency. As a result, the characteristic of a broken line B in FIG. 3 is obtained, which enables to suppress the gain in a lower frequency band. In a band from 800 MHz to 1 GHz, the appropriate value of the capacitor C₂ is at most 15 pF. If the capacitor C₂ develops 1000 pF, the characteristic becomes as shown by the solid line A of FIG. 3, and hence the gain for the lower frequency signal becomes excessive, moreover, due to the effect of the wire inductance L₅, the circuit is set to a state in which the oscillation is quite easily started. Under these conditions, the provisions described above are indispensable in the dc-coupled multistage amplifier circuit. In addition, if a dumping resistor R₂₀ is inserted for the capacitor C₂, an operation for a broad band can be ensured. The filer circuit 11 is not restricted by the configuration shown in the diagram, namely, various resonance circuits, such as those including capacitors and inductances, are available.

The second feature of the circuit shown in FIG. 2 resides in the resistor R₁₂ and the filter circuit 12, which will be described herebelow.

Depending on usages of the amplifier for a high frequency signal of FIG. 2, for example, when it is required to obtain a sharp frequency characteristic or when a feedback-type oscillation circuit using a solid-state element filter is to be configured, the phase characteristic of the solid-state element is fixed; consequently, it is required to insert a phase shifter to adjust the frequency. The resistor R₁₂ and the filter circuit 12 are disposed to easily attain the sharp frequency characteristic and to facilitate the phase shifting operation.

In FIG. 2, the resistor R₁₂ is inserted between the collector of the transistor Q₁ and the base of the transistor Q₂. In this case, if the dc amplification factor h_(fe) of the transistor Q₂ is about 100, the potential drop due to the resistor R₁₂ is almost ignorable. Since the resistance of the resistor R₁₂ is about 6.8KΩ, the dc component can be passed therethrough without allowin the high-frequency signal to pass. A choke coil may be disposed in place of the resistor R₁₂. An intersection of the collector of the transistor Q₁ and the resistor R₁₂ is connected via the wire inductance L₃ to an external terminal ○3 . On the other hand, an external pin ○4 is disposed and is connected via the wire inductance L₄ to an intersection of the base of the transistor Q₂ and the resistor R₁₂ ; furthermore, the filter circuit is inserted between the external terminals ○3 and ○4 .

The filter circuit may be configured as shown in FIG. 4. In this diagram, the wire inductances L₃ and L₄ are absorbed in the capacitors C₁₁ and C₁₂, and hence the circuit is capacitive in the frequency range below the resonance point. A band-pass filter can be constituted with the capacitor C (C₁₁ and C₁₂) and the inductance L₁₁, and the frequency characteristic thereof is sharp as indicated by the line B in FIG. 5. In addition, the change in the phase characteristic is also sharp in the neighborhood of the peak frequency, and hence the phase characteristic can be varied only by slightly shifting the peak frequency, that is, an effect of a phase shifter can also be developed. This is therefore effective when the circuit of FIG. 2 is used as a feedback-type oscillation circuit using a solid-state element filter. According to the configuration of FIG. 2, a gain from 17 dB to 20 dB is attained for the frequency range from 800 MHz to 1 GHz between the input terminal IN and the output terminal OUT. Moreover, if the gain is to be increased by 10 dB, for example, in the configuration of FIG. 2, such an increase cannot be achieved only by changing the constant of each element of FIG. 2, namely, there exits a problem that the gain cannot be easily improved under restrictions that the chip area (the number of elements) and the current are not increased.

FIGS. 6-7 show an amplifier for a high frequency signal which solves the problem. In this diagram, reference numeral 21 is a first amplifying circuit including transistors Q₁ and Q₂ for amplifying a high-frequency signal inputted from the input terminal IN. Reference numeral 22 indicates a second amplifying circuit for amplifying a signal having a desired frequency which is supplied from the output terminal of the first amplifying circuit 21 via a filter circuit 23. In FIG. 2, a transistor Q₃ functioning as an emitter follower for the impedance conversion is also used as the second amplifying circuit 22, thereby attaining the necessary gain together with the first amplifying circuit 21. An output signal having a high frequency is delivered from an output terminal of the second amplifying circuit 22. In this case, to prevent a feedback from the emitter of the second amplifying circuit 22 to the first amplifying circuit 21, a filter circuit 25 is connected to the emitter to lower the im impedance of the emitter. Reference numeral 24 is a regulated voltage source which supplies a bias voltage to the second amplifying circuit 22 so that the operation of the circuit is kept stabilized regardless of the change in the source voltage.

FIG. 7 shows a concrete circuit configuration of FIG. 6.

FIG. 7 shows a case where the circuit is configured by use of an 8-pin integrated circuit. The package pins and chip are connected with wire inductances L₁, L₂, and L₅ to L₁₀ each formed with a bonding wire having an inductance value from 2.5 nH to 5 nH. An input signal having a high frequency is supplied from the input terminal IN via the coupling capacitor C₁ to pin ○1 and is further fed via the wire inductance L₁ to the base of the transistor Q₁ constituting the grounded emitter type amplifier. The emitter of the transistor Q₁ is connected to the grounding in the chip and further via the wire inductance L₂ to pin ○2 . which is in turn connected to the external grounding. The collector of the transistor Q₁ is connected via the load resistor R₁₁ to the emitter of the transistor Q₃ constituting the regulated voltage source.

The collector of the transistor Q₁ is connected to the base of the second transistor Q₂ constituting the grounded-emitter type amplifier. The collector of the transistor Q₂ is connected via the load resistor R₁₂ to the emitter of the transistor Q₃. The emitter of the transistor Q₂ has three directions. The first signal path is used to apply a divided potential divided by the resistors R₁₄ and R₁₅ to the base of the transistor Q₁, thereby establishing the negative dc feedback. The second signal path of the emitter of the transistor Q₂ is connected via the resistor R₁₃ to the grounding in the chip. The third signal path of the emitter of the transistor Q₂ is connected to the external grounding via the wire inductance L₅ as well as the capacitor C₂ and the dumping resistor R₂₀ for the resonance.

An output signal amplified by the first amplifying circuit 1 is fed from the collector of the transistor Q₂ via the wire inductance L₆ to pin ○4 , and is further passed through the external filter circuit 23 for extracting a desired signal and is delivered from pin ○5 via the wire inductance L₅ to the base of the transistor Q₃. A fixed voltage is applied via the resistor having a high resistance to the base of the transistor Q₃. The collector of the transistor Q₃ is connected to the load resistor R₁₉ to the power V_(cc) (about +12 V) line. Since the base of the transistor Q₃ is fixed to a regulated potential with respect to a direct current, the emitter of the transistor Q₃ is fixed to a constant potential with respect to a direct current. The emitter of the tarnsistor Q₃ is connected to the load resistors R₁₁ and R₁₆, and at the same time, is connected via the wire inductance L.sub. 9 to pin ○7 and is finally grounded via the filter circuit 25 disposed outside the integrated circuit. This allows the emitter of the transistor Q₃ to be set to a low impedance with respect to a desired frequency.

FIGS. 8A, B show another example of the filter circuit 25.

The constant voltage applied to the base of the transistor Q₃ is generated by the regulated voltage source 24 comprising the resistor R₅ and the transistors Q₄ -Q₇. By use of the zener voltage between the emitter and the base of the transistor Q₄, the potential is increased through the three transistors Q₅ -Q₇ each being used as a diode by connecting the collector and the base thereof, and the resultant potential is applied to the base of the transistor Q₃. A bias is supplied thereto from the power supply V_(cc) via the resistor R₁₇. The regulated potential is applied via the resistor R₁₈ having a high resistance to the base of the transistor Q₃. The output signal is fed from the collector of the transistor Q₃ through the wire inductance L₁₀, pin ○8 , and the capacitor C₃ disposed to connect an external device.

In the amplifier thus configured, when compared with that of FIG. 2, in place of the sum of the current passing through the transistors Q₁ and Q₂ of FIG. 2, namely, the total I₁ =I₃ +I₄, the total of the current I₃ and I₄ flowing through the transistors Q₁ and Q₂, respectively of FIG. 7 can be set to a value at most the total I₃ +I₄ of FIG. 2. In this case, since the current I₃ +I₄ ÷I₁ flows through the transistor Q₃, it is quite easy to attain a gain at least 10 dB by this transistor Q₃ ; consequently, a sufficient gain can be obtained together with the gain of the first amplifier 1.

In the circuit configured as described above, when compared with the configuration of FIG. 2, the increase of the gain and the improvement of the distortion characteristic due to the increase of the current passing through the third transistor Q₃ can be accomplished without increasing the current and the number of elements.

FIG. 9 is a circuit configuration in a case where the amplifier for a high-frequency signal is used as a first intermediate-frequency amplifier of a converter for CATV. In FIG. 9, a signal inputted from a terminal A is mixed with a signal from a first local oscillator 32 in a first mixer 31 and is subjected to a frequency conversion so as to be converted into a first intermediate-frequency signal (to be referred to as a first IF signal herebelow), for example, a signal in the frequency band from 800 MHz to 1 GHz. The first IF signal is connected to a preamplifier 2, however, if a filter in the next stage develops a reduced loss, the preamplifier 2 is omitted. Reference numeral 34 is a band-pass filter which attenuates a signal having a frequency other than that of the first IF signal. The first IF signal is amplified by a first IF amplifier 35. The circuit of FIG. 2 or 7 may be used as the first IF amplifier. The amplified signal is mixed with a signal from the second local oscillator 37 in the second mixer 36 so as to be converted into a second intermediate-frequency signal (to be referred to as a second IF signal herebelow). In a case of a converter, the signal is converted into a signal having a frequency of a channel and is amplified by the second amplifier 6 to be outputted to the terminal B.

However, in a tuner of a converter of the up-down system using such two local oscillators, although an advantage is developed that the image disturbance can be prevented by increasing the first intermediate-frequency so as to set the image frequency to a frequency band outside those of the broadcasing signal, if the out-band attenuation factor of the band-pass filter 3 is not satisfactory, the image disturbance occurs for the following frequencies.

That is, assuming

First intermediate frequency . . . f_(i1)

Second intermediate frequency . . . f_(i2)

Input signal frequency . . . f_(d)

First local oscillator frequency . . . f_(l1)

Second local oscillator frequency . . . f_(l2)

then, since f_(l1) =f_(d) +f_(i1) and f_(l2) -f_(i2) hold, f_(l1) -f_(d) =f_(i1) is obtained in the first mixer 31 in the normal operation, while f_(i1) -f_(l2) =f_(i2) results from the second mixer 36, thereby obtaining the input signal f_(i2). Under these conditions, when the image signal, namely, f_(d) +2f_(i2) is inputted,

    f.sub.l1 -(f.sub.d +2f.sub.i2)=(f.sub.i1 +f.sub.d)-(f.sub.d +2f.sub.i2)=f.sub.i1 -2f.sub.i2

is obtained in the first mixer 31, and when this signal is supplied to the second mixer 36,

    f.sub.l2 -(f.sub.i1 -2f.sub.i2)=(f.sub.i1 -f.sub.i2)-(f.sub.i1 -2f.sub.i2)=f.sub.i2

is resulted, that is, the signal having the image frequency also appears as f_(i2) in the output, which leads to a problem that the image disturbance also occurs.

The circuit shown in FIG. 10 solves this problem. In this circuit, a trap circuit is inserted between the second IF amplifier and the second mixer to prevent the image disturbance. In FIG. 10, reference numeral 39 is the image trap circuit inserted between the first IF amplifier 35 and the second mixer 36. This image trap circuit 39 is disposed to remove the signal having the frequency equal to f_(i1) -2f_(i2).

FIG. 11 shows a further concrete circuit configuration. In FIG. 11, reference numeral 34 is a band-pass filter using an acoustic surface wave device and developing the characteristic of FIG. 13; R₃₉, C₃₉, and L₃₉ constitute the image trap circuit 39, R₃₉ indicates a resistor, C₃₉ and C₄₀ are cpacitors, and L₃₉ indicates an inductance. This trap circuit 39 is connected to the second mixer 36 of the differential type in the next stage.

Assuming the capacitance of the capacitor C₃₉, capacitance of the capacitor C₄₀, and the inductance value of the inductance L₃₉ to be C₃₉, C₄₀, and L₃₉, respectively, the series resonance point and the parallel resonance point are expressed as ##EQU1## that is, the trap characteristic of FIG. 12 is developed. Setting ω₁ =2π(f_(i1) -2f_(i2)) and ω₀ =f_(i1), then the series resonance trap is formed with respect to the image frequency, while the parallel resonance is established with respect to the first intermediate frequency f_(i1), that is, the first intermediate frequency f_(i1) can pass through the signal line.

Moreover, if a trap circuit in a configuration shown in FIG. 14a is inserted between the signal line and the grounding and the constants are selected so that the series resonance point ω₁ =f_(i1) -2f_(i2) and the parallel resonance point ω₀ are set between ω₂ (f_(i2)) and ω₁, then the trap is formed for the image frequency, and the circuit becomes inductive for a frequency exceeding the image frequency; consequently, the first intermediate frequency f_(i1) passes through the signal line. For a low frequency of the second intermediate frequency f_(i2), although the circuit is inductive, the impedance is low, and hence the signal having the second intermediate frequency f_(i2) is led via the trap circuit to the grounding. As a consequence, for the second mixer 32 connected in the next stage, the image filter for ordinarily attenuating f_(i2) can be configured at the same time. In addition, if the first amplifier 35 and the second mixer 36 are configured in an IC and the mixer input is extracted through an IC pin, a trap can be formed.

Industrial Applicability

According to the present invention as described above, a circuit including at least two stages of dc-coupled grounded-emitter type amplifiers are constructed in an integrated circuit, and an emitter resistor is inserted between the emitter of the second-stage amplifier and the grounding, moreover, the emitter of the second-stage amplifier is connected via a bonding wire to a terminal outside the integrated circuit and a filter circuit indluding the inductance of the bonding wire is formed between the external terminal and the grounding so as to connect a signal having a particular frequency to an external grounding by use of the filter circuit, which prevents the feedback due to the emitter resistor and an unstable state in which the oscillation occurs, namely, this circuit is suitable as an amplifier for a high-frequency signal in a television tuner circuit, a receiver for satellite broadcasting, and the like. 

We claim:
 1. An amplifier for a high frequency signal in which an integrated circuit including at least two stages of DC coupled ground-emitter type amplifiers is configured, an emitter resistor is connected between an emitter of a grounded-emitter amplifier in a subsequent stage and a ground, a terminal is disposed outside the integrated circuit so as to be connected via a bonding wire to said emitter of the grounded-emitter type amplifier in said subsequent stage, and a first filter circuit including an inductance of the bonding wire and developing a low impedance for a particular frequency is disposed between said terminal and an external ground, said at least two grounded-emitter type amplifiers are supplied with a constant voltage via an emitter-follower transistor, a second filter circuit allowing a particular frequency to pass therethrough is inserted between a collector output of said grounded-emitter type amplifier in said subsequent stage and a base of said emitter-follower transistor, an input signal is amplified by said grounded-emitter type amplifiers and said emitter follower transistor, and the amplified signal is outputted from a collector of said emitter-follower transistor.
 2. An amplifier according to claim 1, wherein a third filter circuit developing a low impedance for a particular frequency is inserted between an emitter of said emitter-follower transistor and said external ground.
 3. An amplifier according to claim 1, wherein a trap circuit preventing an image disturbance is disposed at an end from which the amplified signal having a high frequency is outputted. 